|Publication number||US8055832 B2|
|Application number||US 11/382,224|
|Publication date||Nov 8, 2011|
|Filing date||May 8, 2006|
|Priority date||Aug 3, 2005|
|Also published as||CN101233479A, CN101233479B, CN101233480A, CN101233480B, CN101233498A, CN101233498B, CN101233499A, CN101258473A, CN101258473B, CN101278267A, CN101278267B, CN101288045A, CN101288045B, EP1920336A2, EP1920337A2, US7409489, US7450420, US7558905, US7562181, US7581057, US7590794, US7590795, US7610437, US7984084, US8291151, US20070030734, US20070033324, US20070033325, US20070033326, US20070033327, US20070033328, US20070033329, US20070033330, US20070033376, US20070033377, US20070033378, US20070186032, WO2007019174A2, WO2007019174A3, WO2007019220A2, WO2007019220A3|
|Publication number||11382224, 382224, US 8055832 B2, US 8055832B2, US-B2-8055832, US8055832 B2, US8055832B2|
|Inventors||Alan W. Sinclair, Barry Wright|
|Original Assignee||SanDisk Technologies, Inc.|
|Export Citation||BiBTeX, EndNote, RefMan|
|Patent Citations (180), Non-Patent Citations (30), Referenced by (3), Classifications (27), Legal Events (3)|
|External Links: USPTO, USPTO Assignment, Espacenet|
The benefit is claimed of U.S. provisional patent application of Alan W. Sinclair and Barry Wright, Ser. No. 60/705,388, filed Aug. 3, 2005.
This application is also related to U.S. patent application Ser. No. 11/060,174, now publication no. 2006/0184718 A1, Ser. No. 11/060,248, now publication no. 2006/0184719 A1 and Ser. No. 11/060,249, now publication no. 2006/0184720 A1, all filed on Feb. 16, 2005, naming as inventors either Alan W. Sinclair alone or with Peter J. Smith.
This application is also related to three U.S. patent applications of Alan W. Sinclair and Barry Wright, Ser. No. 11/382,228, now publication no. 2007/0033329 A1, entitled “Memory System With Management of Memory Blocks That Directly Store Data Files,” Ser. No. 11/382,232, now publication no. 2007/0030734 A1, entitled “Reclaiming Data Storage Capacity in Flash Memories,” Ser. No. 11/382,235, now publication no. 2007/0033330 A1, entitled “Reclaiming Data Storage Capacity in Flash Memory Systems,” and to two provisional applications by them, No. 60/746,742, entitled “File Data Indexing in Flash Memory” and No. 60/746,740, entitled “Content Addressable Lists in Flash Memory,” all filed on May 8, 2006.
This application relates to the operation of re-programmable non-volatile memory systems such as semiconductor flash memory, and, more specifically, to the management of the interface between a host device and the memory.
There are two primary techniques by which data communicated through external interfaces of host systems, memory systems and other electronic systems are addressed. In one of them, addresses of data files generated or received by the system are mapped into distinct ranges of a continuous logical address space established for the system. The extent of the address space is typically sufficient to cover the full range of addresses that the system is capable of handling. In one example, magnetic disk storage drives communicate with computers or other host systems through such a logical address space. This address space has an extent sufficient to address the entire data storage capacity of the disk drive. In the second of the two techniques, data files generated or received by an electronic system are uniquely identified and their data logically addressed by offsets within the file. A form of this addressing method is used between computers or other host systems and a removable memory card known as a “Smart Card.” Smart Cards are typically used by consumers for identification, banking, point-of-sale purchases, ATM access and the like.
In an early generation of commercial flash memory systems, a rectangular array of memory cells were divided into a large number of groups of cells that each stored the amount of data of a standard disk drive sector, namely 512 bytes. An additional amount of data, such as 16 bytes, are also usually included in each group to store an error correction code (ECC) and possibly other overhead data relating to the user data and/or to the memory cell group in which the associated user data are stored. The memory cells in each such group are the minimum number of memory cells that are erasable together. That is, the erase unit is effectively the number of memory cells that store one data sector and any overhead data that is included. Examples of this type of memory system are described in U.S. Pat. Nos. 5,602,987 and 6,426,893. It is a characteristic of flash memory that the memory cells are erased prior to re-programming them with data.
Flash memory systems are most commonly provided in the form of a memory card or flash drive that is removably connected with a variety of hosts such as a personal computer, a camera or the like, but may also be embedded within such host systems. When writing data to the memory, the host typically assigns unique logical addresses to sectors, clusters or other units of data within a continuous virtual address space of the memory system. Like a disk operating system (DOS), the host writes data to, and reads data from, addresses within the logical address space of the memory system. A controller within the memory system translates logical addresses received from the host into physical addresses within the memory array, where the data are actually stored, and then keeps track of these address translations. The data storage capacity of the memory system is at least as large as the amount of data that is addressable over the entire logical address space defined for the memory system.
In later generations of flash memory systems, the size of the erase unit was increased to a block of enough memory cells to store multiple sectors of data. Even though host systems with which the memory systems are connected may program and read data in small minimum units such as sectors, a large number of sectors are stored in a single erase unit of the flash memory. It is common for some sectors of data within a block to become obsolete as the host updates or replaces logical sectors of data. Since the entire block must be erased before any data stored in the block can be overwritten, new or updated data are typically stored in another block that has been erased and has remaining capacity for the data. This process leaves the original block with obsolete data that take valuable space within the memory. But that block cannot be erased if there are any valid data remaining in it.
Therefore, in order to better utilize the memory's storage capacity, it is common to consolidate or collect valid partial block amounts of data by copying them into an erased block so that the block(s) from which these data are copied may then be erased and their entire storage capacity reused. It is also desirable to copy the data in order to group data sectors within a block in the order of their logical addresses since this increases the speed of reading the data and transferring the read data to the host. If such data copying occurs too frequently, the operating performance of the memory system can be degraded. This particularly affects operation of memory systems where the storage capacity of the memory is little more than the amount of data addressable by the host through the logical address space of the system, a typical case. In this case, data consolidation or collection may be required before a host programming command can be executed. The programming time is then increased as a result.
The sizes of the blocks have been increasing in successive generations of memory systems in order to increase the number of bits of data that may be stored in a given semiconductor area. Blocks storing 256 data sectors and more are becoming common. Additionally, two, four or more blocks of different arrays or sub-arrays are often logically linked together into metablocks in order to increase the degree of parallelism in data programming and reading. Along with such large capacity operating units come challenges in operating them efficiently.
A common host interface for such memory systems is a logical address interface similar to that commonly used with disk drives. Files generated by a host to which the memory is connected are assigned unique addresses within the logical address space of the interface. The memory system then commonly maps data between the logical address space and the physical blocks or metablocks of the memory. The memory system keeps track of how the logical address space is mapped into the physical memory but the host is unaware of this. The host keeps track of the addresses of its data files within the logical address space but the memory system operates without knowledge of this mapping.
Many techniques have been developed that overcome to various degrees certain of the problems encountered in efficiently operating such large erase block flash memory systems. The present invention, on the other hand, is based upon a fundamental change, namely by changing the data transfer interface between the memory and the host system. Rather than communicating data between them by the use of logical addresses within a virtual address space, a data file is identified by a filename assigned by the host and its accessed by offset address within the file. The memory system then knows the host file to which each sector or other unit of data belongs. The file unit being discussed herein is a set of data that is ordered, such as by having sequential offset addresses, and which is created and uniquely identified by an application program operating in a host computing system.
This is not employed by most current commercial memory systems since hosts now identify data to the memory system within all files by a common set of logical addresses without identifying the files. By identifying host data by file objects instead of using logical addresses, the memory system controller can store the data in a manner that reduces the need for such frequent data consolidation and garbage collection. The frequency of data copy operations and the amount of data copied are thus significantly reduced, thereby increasing the data programming and reading performance of the memory system. Further, the memory system controller maintains directory and index table information of the memory blocks into which host files are stored. It is then unnecessary for the host to maintain the file allocation table (FAT) that is currently necessary for managing a logical address interface.
In accordance with an aspect of the present invention, memory blocks are selected for writing data of files by a method that controls the degree of fragmentation of the files throughout different blocks of the memory. This reduces the number and frequency of overhead operations that need be performed to combine data of a file into a lesser number of blocks in order to free up fully erased blocks to receive new data. Performance of the memory system is thus improved by initially selecting a block into which data of a file are to be written and relying less on later moving data between blocks in order to utilize the full capacity of the memory in an efficient manner.
In a specific embodiment, a type of active block is selected to write data of a file received from a host or another block on the basis of the types of blocks in which data of the file are already stored. One of a number of permitted states is assigned to each file stored in the system, each state being defined by combinations of one or more types of blocks that contain data of two or more files and/or that contain erased capacity. A type of block that is selected as an active block, into which data of a file are written, is based on the current state of the file.
Other aspects, advantages, features and details of the present invention are included in a description of exemplary examples thereof that follows, which description should be taken in conjunction with the accompanying drawings.
All patents, patent applications, articles, other publications, documents and things referenced herein are hereby incorporated herein by this reference in their entirety for all purposes. To the extent of any inconsistency or conflict in the definition or use of terms between any of the incorporated publications, documents or things and the present application, those of the present application shall prevail.
A common flash memory system and a typical operation with host devices are described with respect to
Host systems that use such memory cards and flash drives are many and varied. They include personal computers (PCs), laptop and other portable computers, cellular telephones, personal digital assistants (PDAs), digital still cameras, digital movie cameras and portable audio players. The host typically includes a built-in receptacle for one or more types of memory cards or flash drives but some require adapters into which a memory card is plugged. The memory system usually contains its own memory controller and drivers but there are also some memory only systems that are instead controlled by software executed by the host to which the memory is connected. In some memory systems containing the controller, especially those embedded within a host, the memory, controller and drivers are often formed on a single integrated circuit chip.
The host system 1 of
The memory system 2 of
A typical controller chip 11 has its own internal bus 23 that interfaces with the system bus 13 through interface circuits 25. The primary functions normally connected to the bus are a processor 27 (such as a microprocessor or micro-controller), a read-only-memory (ROM) 29 containing code to initialize (“boot”) the system, read-only-memory (RAM) 31 used primarily to buffer data being transferred between the memory and a host, and circuits 33 that calculate and check an error correction code (ECC) for data passing through the controller between the memory and the host. The controller bus 23 interfaces with a host system through circuits 35, which, in the case of the system of
The memory chip 15, as well as any other connected with the system bus 13, typically contains an array of memory cells organized into multiple sub-arrays or planes, two such planes 41 and 43 being illustrated for simplicity but more, such as four or eight such planes, may instead be used. Alternatively, the memory cell array of the chip 15 may not be divided into planes. When so divided however, each plane has its own column control circuits 45 and 47 that are operable largely independently of each other. The circuits 45 and 47 receive addresses of their respective memory cell array from the address portion 19 of the system bus 13, and decode them to address a specific one or more of respective bit lines 49 and 51. The word lines 53 are addressed through row control circuits 55 in response to addresses received on the address bus 19. Source voltage control circuits 57 and 59 are also connected with the respective planes, as are p-well voltage control circuits 61 and 63. If the memory chip 15 has a single array of memory cells, and if two or more such chips exist in the system, the array of each chip may be operated similarly to a plane or sub-array within the multi-plane chip described above.
Data are transferred into and out of the planes 41 and 43 through respective data input/output circuits 65 and 67 that are connected with the data portion 17 of the system bus 13. The circuits 65 and 67 provide for both programming data into the memory cells and for reading data from the memory cells of their respective planes, through lines 69 and 71 connected to the planes through respective column control circuits 45 and 47.
Although the controller 11 controls the operation of the memory chip 15 to program data, read data, erase and attend to various housekeeping matters, each memory chip also contains some controlling circuitry that executes commands from the controller 11 to perform such functions. Interface circuits 73 are connected to the control and status portion 21 of the system bus 13. Commands from the controller are provided to a state machine 75 that then provides specific control of other circuits in order to execute these commands. Control lines 77-81 connect the state machine 75 with these other circuits as shown in
A NAND architecture of the memory cell arrays 41 and 43 is currently preferred, although other architectures, such as NOR, can also be used instead. Examples of NAND flash memories and their operation as part of a memory system may be had by reference to U.S. Pat. Nos. 5,570,315, 5,774,397, 6,046,935, 6,373,746, 6,456,528, 6,522,580, 6,771,536 and 6,781,877 and U.S. patent application publication no. 2003/0147278.
An example NAND array is illustrated by the circuit diagram of
Word lines 115-118 of
A second block 125 is similar, its strings of memory cells being connected to the same global bit lines as the strings in the first block 123 but having a different set of word and control gate lines. The word and control gate lines are driven to their proper operating voltages by the row control circuits 55. If there is more than one plane or sub-array in the system, such as planes 1 and 2 of
As described in several of the NAND patents and published application referenced above, the memory system may be operated to store more than two detectable levels of charge in each charge storage element or region, thereby to store more than one bit of data in each. The charge storage elements of the memory cells are most commonly conductive floating gates but may alternatively be non-conductive dielectric charge trapping material, as described in United States patent application publication no. 2003/0109093.
The individual blocks are in turn divided for operational purposes into pages of memory cells, as illustrated in
Although it is preferable to program and read the maximum amount of data in parallel across all four planes, for high system performance, the memory system can also be operated to form metapages of any or all of one, two or three pages in separate blocks in different planes. This allows the programming and reading operations to adaptively match the amount of data that may be conveniently handled in parallel and reduces the occasions when part of a metapage remains unprogrammed with data.
A metapage formed of physical pages of multiple planes, as illustrated in
With reference to
The amount of data in each logical page is typically an integer number of one or more sectors of data, each sector containing 512 bytes of data, by convention.
As the parallelism of memories increases, data storage capacity of the metablock increases and the size of the data page and metapage also increase as a result. The data page may then contain more than two sectors of data. With two sectors in a data page, and two data pages per metapage, there are four sectors in a metapage. Each metapage thus stores 2048 bytes of data. This is a high degree of parallelism, and can be increased even further as the number of memory cells in the rows are increased. For this reason, the width of flash memories is being extended in order to increase the amount of data in a page and a metapage.
The physically small re-programmable non-volatile memory cards and flash drives identified above are commercially available with data storage capacity of 512 megabytes (MB), 1 gigabyte (GB), 2 GB and 4 GB, and may go higher.
A common logical interface between the host and the memory system is illustrated in
Three Files 1, 2 and 3 are shown in the example of
When a File 2 is later created by the host, the host similarly assigns two different ranges of contiguous addresses within the logical address space 161, as shown in
The host keeps track of the memory logical address space by maintaining a file allocation table (FAT), where the logical addresses assigned by the host to the various host files by the conversion 160 are maintained. The FAT table is frequently updated by the host as new files are stored, other files deleted, files modified and the like. The FAT table is typically stored in a host memory, with a copy also stored in the non-volatile memory that is updated from time to time. The copy is typically accessed in the non-volatile memory through the logical address space just like any other data file. When a host file is deleted, the host then deallocates the logical addresses previously allocated to the deleted file by updating the FAT table to show that they are now available for use with other data files.
The host is not concerned about the physical locations where the memory system controller chooses to store the files. The typical host only knows its logical address space and the logical addresses that it has allocated to its various files. The memory system, on the other hand, through a typical host/card interface, only knows the portions of the logical address space to which data have been written but does not know the logical addresses allocated to specific host files, or even the number of host files. The memory system controller converts the logical addresses provided by the host for the storage or retrieval of data into unique physical addresses within the flash memory cell array where host data are stored. A block 163 represents a working table of these logical-to-physical address conversions, which is maintained by the memory system controller.
The memory system controller is programmed to store data files within the blocks and metablocks of a memory array 165 in a manner to maintain the performance of the system at a high level. Four planes or sub-arrays are used in this illustration. Data are preferably programmed and read with the maximum degree of parallelism that the system allows, across an entire metablock formed of a block from each of the planes. At least one metablock 167 is usually allocated as a reserved block for storing operating firmware and data used by the memory controller. Another metablock 169, or multiple metablocks, may be allocated for storage of host operating software, the host FAT table and the like. Most of the physical storage space remains for the storage of data files. The memory controller does not know, however, how the data received has been allocated by the host among its various file objects. All the memory controller typically knows from interacting with the host is that data written by the host to specific logical addresses are stored in corresponding physical addresses as maintained by the controller's logical-to-physical address table 163.
In a typical memory system, a few extra blocks of storage capacity are provided than are necessary to store the amount of data within the address space 161. One or more of these extra blocks may be provided as redundant blocks for substitution for other blocks that may become defective during the lifetime of the memory. The logical grouping of blocks contained within individual metablocks may usually be changed for various reasons, including the substitution of a redundant block for a defective block originally assigned to the metablock. One or more additional blocks, such as metablock 171, are typically maintained in an erased block pool. When the host writes data to the memory system, the controller converts the logical addresses assigned by the host to physical addresses within a metablock in the erased block pool. Other metablocks not being used to store data within the logical address space 161 are then erased and designated as erased pool blocks for use during a subsequent data write operation. In a preferred form, the logical address space is divided into logical groups that each contain an amount of data equal to the storage capacity of a physical memory metablock, thus allowing a one-to-one mapping of the logical groups into the metablocks.
Data stored at specific host logical addresses are frequently overwritten by new data as the original stored data become obsolete. The memory system controller, in response, writes the new data in an erased block and then changes the logical-to-physical address table for those logical addresses to identify the new physical block to which the data at those logical addresses are stored. The blocks containing the original data at those logical addresses are then erased and made available for the storage of new data. Such erasure often must take place before a current data write operation may be completed if there is not enough storage capacity in the pre-erased blocks from the erase block pool at the start of writing. This can adversely impact the system data programming speed. The memory controller typically learns that data at a given logical address has been rendered obsolete by the host only when the host writes new data to their same logical address. Many blocks of the memory can therefore be storing such invalid data for a time.
The sizes of blocks and metablocks are increasing in order to efficiently use the area of the integrated circuit memory chip. This results in a large proportion of individual data writes storing an amount of data that is less than the storage capacity of a metablock, and in many cases even less than that of a block. Since the memory system controller normally directs new data to an erased pool metablock, this can result in portions of metablocks going unfilled. If the new data are updates of some data stored in another metablock, remaining valid metapages of data from that other metablock having logical addresses contiguous with those of the new data metapages are also desirably copied in logical address order into the new metablock. The old metablock may retain other valid data metapages. This results over time in data of certain metapages of an individual metablock being rendered obsolete and invalid, and replaced by new data with the same logical address being written to a different metablock.
In order to maintain enough physical memory space to store data over the entire logical address space 161, such data are periodically compacted or consolidated (garbage collection). It is also desirable to maintain sectors of data within the metablocks in the same order as their logical addresses as much as practical, since this makes reading data in contiguous logical addresses more efficient. So data compaction and garbage collection are typically performed with this additional goal. Some aspects of managing a memory when receiving partial block data updates and the use of metablocks are described in U.S. Pat. No. 6,763,424.
Data compaction typically involves reading all valid data metapages from a metablock and writing them to a new metablock, ignoring metapages with invalid data in the process. The metapages with valid data are also preferably arranged with a physical address order that matches the logical address order of the data stored in them. The number of metapages occupied in the new metablock will be less than those occupied in the old metablock since the metapages containing invalid data are not copied to the new metablock. The old block is then erased and made available to store new data. The additional metapages of capacity gained by the consolidation can then be used to store other data.
During garbage collection, metapages of valid data with contiguous or near contiguous logical addresses are gathered from two or more metablocks and re-written into another metablock, usually one in the erased block pool. When all valid data metapages are copied from the original two or more metablocks, they may be erased for future use.
Data consolidation and garbage collection take time and can affect the performance of the memory system, particularly if data consolidation or garbage collection needs to take place before a command from the host can be executed. Such operations are normally scheduled by the memory system controller to take place in the background as much as possible but the need to perform these operations can cause the controller to have to give the host a busy status signal until such an operation is completed. An example of where execution of a host command can be delayed is where there are not enough pre-erased metablocks in the erased block pool to store all the data that the host wants to write into the memory and data consolidation or garbage collection is needed first to clear one or more metablocks of valid data, which can then be erased. Attention has therefore been directed to managing control of the memory in order to minimize such disruptions. Many such techniques are described in the following U.S. patent applications: Ser. No. 10/749,831, filed Dec. 30, 2003, entitled “Management of Non-Volatile Memory Systems Having Large Erase Blocks,” now publication no. 2005/0144358 A1; Ser. No. 10/750,155, filed Dec. 30, 2003, entitled “Non-Volatile Memory and Method with Block Management System,” now publication no. 2005/0144360 A1; Ser. No. 10/917,888, filed Aug. 13, 2004, entitled “Non-Volatile Memory and Method with Memory Planes Alignment,” now publication no. 2005/0141313 A1; Ser. No. 10/917,867, filed Aug. 13, 2004, now publication no. 2005/0141312 A1; Ser. No. 10/917,889, filed Aug. 13, 2004, entitled “Non-Volatile Memory and Method with Phased Program Failure Handling,” now publication no. 2005/0166087 A1; Ser. No. 10/917,725, filed Aug. 13, 2004, entitled “Non-Volatile Memory and Method with Control Data Management,” now publication no. 2005/0144365 A1; Ser. No. 11/192,220, filed Jul. 27, 2005, entitled “Non-Volatile Memory and Method with Multi-Stream Update Tracking,” now publication no. 2006/0155921 A1; Ser. No. 11/192,386, filed Jul. 27, 2005, entitled “Non-Volatile Memory and Method with Improved Indexing for Scratch Pad and Update Blocks,” now publication no. 2006/0155922 A1; and Ser. No. 11/191,686, filed Jul. 27, 2005, entitled “Non-Volatile Memory and Method with Multi-Stream Updating,” now publication no. 2006/0155920 A1.
One challenge to efficiently control operation of memory arrays with very large erase blocks is to match and align the number of data sectors being stored during a given write operation with the capacity and boundaries of blocks of memory. One approach is to configure a metablock used to store new data from the host with less than a maximum number of blocks, as necessary to store a quantity of data less than an amount that fills an entire metablock. The use of adaptive metablocks is described in U.S. patent application Ser. No. 10/749,189, filed Dec. 30, 2003, entitled “Adaptive Metablocks,” now publication no. 2005/0144357 A1. The fitting of boundaries between blocks of data and physical boundaries between metablocks is described in patent application Ser. No. 10/841,118, filed May 7, 2004, now publication no. 2005/0144363 A1, and Ser. No. 11/016,271, filed Dec. 16, 2004, now publication no. 2005/0144367 A1, entitled “Data Run Programming.”
The memory controller may also use data from the FAT table, which is stored by the host in the non-volatile memory, to more efficiently operate the memory system. One such use is to learn when data has been identified by the host to be obsolete by deallocating their logical addresses. Knowing this allows the memory controller to schedule erasure of the blocks containing such invalid data before it would normally learn of it by the host writing new data to those logical addresses. This is described in U.S. patent application Ser. No. 10/897,049, filed Jul. 21, 2004, entitled “Method and Apparatus for Maintaining Data on Non-Volatile Memory Systems,” now publication no. 2006/0020744 A1. Other techniques include monitoring host patterns of writing new data to the memory in order to deduce whether a given write operation is a single file, or, if multiple files, where the boundaries between the files lie. U.S. patent application Ser. No. 11/022,369, filed Dec. 23, 2004, entitled “FAT Analysis for Optimized Sequential Cluster Management,” now publication no. 2006/0020745 A1, describes the use of techniques of this type.
To operate the memory system efficiently, it is desirable for the controller to know as much about the logical addresses assigned by the host to data of its individual files as it can. Data files can then be stored by the controller within a single metablock or group of metablocks, rather than being scattered among a larger number of metablocks when file boundaries are not known. The result is that the number and complexity of data consolidation and garbage collection operations are reduced. The performance of the memory system improves as a result. But it is difficult for the memory controller to know much about the host data file structure when the host/memory interface includes the logical address space 161 (
A different type of interface between a host and memory system for the storage of mass amounts of data eliminates use of the logical address space. The host instead logically addresses each file by a unique fileID (or other unique reference) and offset addresses of units of data (such as bytes) within the file. This file address is given directly to the memory system controller, which then keeps its own table of where the data of each host file are physically stored. This new interface can be implemented with the same memory system as described above with respect to
This file-based interface is illustrated in
The file-based interface is also illustrated by
A file block management function 605 organizes storage of data in flash memory according to the files by which the data is identified, and minimizes the incidence of blocks storing data for more than one file. The physical block of memory cells of the memory 603 is the basic unit of data management.
Data are organized into metapages by a function 607 for writing into the memory 603, such that individual metapages contain data for a contiguous logical offset address range within a specific file. A function 609 controls access to the memory 603 for reading data stored therein. The deletion of data of a file, when commanded by the host, causes a function 611 to update file indexing information maintained by a function 613 and lists of blocks in a function 615.
The file data indexing 613 indexes the individual files stored in the memory 603 by a unique file identifier and offset addresses of data within the file. The data for each file are stored as a set of data groups having contiguous logical offset addresses. A file directory identifies the locations in a file index table (FIT) of sets of data group entries for the individual files. The identity of blocks that are erased, either partially programmed with file data or that contain file data together with obsolete data are maintained by the block list function 615.
The primary purpose of the garbage collection and data consolidation functions described above are to reclaim unused memory space for use to store additional data. In garbage collection, valid data of a source block are copied from blocks also containing obsolete data into one or more destination blocks that have at least some erased space. This gathers valid data into a fewer number of blocks, thus freeing up capacity occupied by obsolete data once the original source block(s) are erased. In data consolidation, valid data of one partially filled block, which thus also contains erased but unused space, are combined with valid data of another partially filled block. Partially filled blocks result most commonly from writing a new file that is closed with its last erased block only partially filled. Once data are consolidated, the source blocks containing the data just copied, which are then duplicate data, are then erased and made available for the storage of new data.
Both of the garbage collection and data consolidation operations are handled herein together as block reclamation. A function 617 reclaims blocks by controlling the copying of valid file data from a physical block having unprogrammed metapages, or containing obsolete data, to other blocks. This allows the original block to be erased to reclaim the unused space it contained and make this space available for the storage of new file data. A function 619 adaptively controls the occurrence and duration of block reclaim operations, according to the amount of reclaimable capacity and number of erased blocks. Block reclaim is performed at an optimum rate relative to the rate of writing new file data in a manner that maintains good overall performance of the memory system.
In the functional diagram of
The translation layer 621 includes protocol adaptors 631, 633 and 635 that function to convert the protocols of respective interface protocols 625, 627 and 629 into a common protocol for the file interface 601. Commands, data formats and the like are converted between different protocols by the translation layer. The LBA protocol adaptor 635 additionally divides the logical address space of the memory system into static files. These files are then handled by the file interface 601 in the same manner as distinct files communicated through the interfaces 625 and 627. Details of the function of the LBA protocol adaptor 635 may be had by reference to U.S. patent application Ser. No. 11/196,869, filed Aug. 3, 2005, naming S. A. Gorobets as inventor, now publication no. 2007/0033323 A1. More information of the translation and interface layers 621 and 623 is given in U.S. patent application Ser. No. 11/316,577, filed Dec. 21, 2005, naming Alan Sinclair as inventor, now publication no. 2007/0033326 A1.
When a new data file is programmed into the memory, the data are written into an erased block of memory cells beginning with the first physical location in the block and proceeding through the locations of the block sequentially in order. The data are programmed in the order received from the host, regardless of the order of the offsets of that data within the file. Programming continues until all data of the file have been written into the memory. If the amount of data in the file exceeds the capacity of a single memory block, then, when the first block is full, programming continues in a second erased block. The second memory block is programmed in the same manner as the first, in order from the first location until either all the data of the file are stored or the second block is full. A third or additional blocks may be programmed with any remaining data of the file. Multiple blocks or metablocks storing data of a single file need not be physically or logically contiguous. For ease of explanation, unless otherwise specified, it is intended that the term “block” as used herein refer to either the block unit of erase or a multiple block “metablock,” depending upon whether metablocks are being used in a specific system.
The state diagram of
A preferred way for the memory system to manage and keep track of the stored data is with the use of variable sized data groups. That is, data of a file are stored as a plurality of groups of data that may be chained together in a defined order to form the complete file. Preferably, however, the order of the data groups within the file is maintained by the memory system controller through use of the file index table (FIT). As a stream of data from the host are being written, a new data group is begun whenever there is a discontinuity either in the logical offset addresses of the file data or in the physical space in which the data are being stored. An example of such a physical discontinuity is when data of a file fills one block and begins to be written into another block. This is illustrated in
The amount of data being transferred through the host-memory interface may be expressed in terms of a number of bytes of data, a number of sectors of data, or with some other granularity. A host most often defines data of its files with byte granularity but then groups bytes into sectors of 512 bytes each, or into clusters of multiple sectors each, when communicating with a large capacity memory system through a current logical address interface. This is usually done to simplify operation of the memory system. Although the file-based host-memory interface being described herein may use some other unit of data, the original host file byte granularity is generally preferred. That is, data offsets, lengths, and the like, are preferably expressed in terms of byte(s), the smallest reasonable unit of data, rather than by sector(s), cluster(s) or the like. This allows more efficient use of the capacity of the flash memory storage with the techniques described herein.
The new file written into the memory in the manner illustrated in
So long as the host maintains the file of
An example of the insertion of a block of data 191 into the previously written file of
As an alternative to the insertion of data into an existing file that is illustrated in
The offsets of the data of each file are preferably maintained continuous in the correct logical order after the file's creation or modification according to the preceding description. Therefore, as part of an operation to insert data into a file, for example, offsets of the inserted data provided by the host are continuous from the offset immediately preceding the insert and data already in the file after the insert are incremented by an amount of the inserted data. Updating an existing file most commonly results in data within a given address range of an existing file being replaced by a like amount of updated data, so the offsets of other data of the file usually need not be replaced.
It will be noted that all of the data allocation and indexing functions described above with respect to
An advantage of directly writing file data from the host into the flash memory in the manner just described is that the granularity or resolution of the data so stored may be maintained the same as that of the host. If a host application writes file data with a one-byte granularity, for example, that data may be also be written into the flash memory with a one-byte granularity. The amount and location of data within an individual data group is then measured in a number of bytes. That is, the same offset unit of data that is separately addressable within the host application file is also separately addressable within that file when stored in the flash memory. Any boundaries between data groups of the same file within a block are then specified in the index table to the nearest byte or other host offset unit. Similarly, boundaries between data groups of different files within a block are defined in the unit of the host offset.
The term “sector” is used herein with large block memories to denote the unit of stored data with which an ECC is associated. The sector is also the minimum unit of data transfer to and from flash memory. A “page” is used to denote a unit of memory cells within a block and is the minimum unit of programming. The term “metapage” is used to denote a page with the full parallelism of a metablock. The metapage is the maximum unit of programming.
An example of the file-to-block mapping function 605 of
The types of blocks recognized in this example that contain file data are as follows:
Another type of block is the “erased block”, where the total capacity of the block is unprogrammed and available to accept data. When the memory is full or nearly full of data, a pool of a specified minimum number of erased blocks is typically maintained by continuously reclaiming unused capacity that exists within blocks that are being used.
A “fractal block” is a collective term that refers to a program block, common block or a full common block. A fractal block for a file contains valid data of the file, together with either unprogrammed memory capacity, valid data for other files, or both. A primary purpose of the techniques described herein is to minimize the number of fractal blocks in a memory system by managing the type of active block that is designated to receive data of a file. This reduces the instances of garbage collection and data consolidation (block reclaim operations) necessary to maintain the specified minimum number of erased blocks. The rate at which data may be written into the memory is then increased since less time is taken for internal copying of data to reclaim fragments of unused capacity in previously programmed blocks.
Additional terms are also used herein to collectively describe other types of blocks:
The example of
The example of
Data of a file may be written directly into erased capacity of a partial block that already contains data of another file, rather than into an erased block, in order to make good use of unprogrammed capacity in this form. This is particularly useful when a known quantity of file data less than the capacity of a full block is to be written. Existing partial blocks are searched to find an amount of erased capacity that fits the known amount of data to be written. The number of pages (or metapages if the metablocks are being used) of data is compared with the number of pages of unprogrammed, erased capacity in partial blocks. When unused erased space of a program block is programmed in this way, it is converted into a common block.
The file A is written in the example of
Although the examples of
It will be noted that blocks 665, 667, 669, 671, 673 and 675 are fractal blocks. It is desired to minimize the number of fractal blocks occupied by data of any one file since their presence increases the likelihood of the need to reclaim unused capacity in them and thus adversely affect system performance. Unused erased capacity exists in partial blocks 665, 669, 673 and 675 but it may not be efficient to write new data from a host directly into this space unless the quantity of unwritten data for a file is known and that known amount matches the unused capacity of one of these blocks. It is most common that the amount of data from the host for a particular file is not known, so these bits of capacity are not readily filled. Data may therefore need to be moved from another block into the unused space during a reclaim operation in order to make efficient use of the memory capacity. Blocks 669, 671 and 675 contain data of more than one file, which means that when one of the files is deleted or its data stored in the common block becomes obsolete, data reclaim will likely be done to reclaim the capacity of the block occupied by obsolete data.
Therefore, in order to reduce the number of time consuming data reclaim operations, data of a particular file are allowed to be stored in only one, two or some other number of fractal blocks at any one time. In the specific example described herein, data of any one file may be stored in two or fewer fractal blocks but no more. A process of designating a new active block to store data of a file is so constrained. One of a set of permitted file states is assigned to each file that is defined by the types of blocks in which data of the file are stored. When a new active block needs to be assigned for receiving data of a particular file, such as when an existing block becomes full, the type of block so designated depends upon the state of the file and, in many cases, also other factors.
Definitions of ten permitted file states 0-9 are given in the table of
Resulting primary transitions among the file states 0-9 defined in
As shown in the table of
But when in file state 0 and data of the new file received from a host has a known length that is less than the storage capacity of a block, a partial block is designated as the active block if one is available with enough erased capacity for storage of the known amount of data. The file has then transitioned from state 0 to state 3 (see
A characteristic of a file in state 2 is that a program block is allocated to receive additional data of the file. But if the file is large enough, the block will eventually become full and another active block then needs to be designated. If the full block, now a file block, contains no obsolete data, the file returns to state 0, where no active block is designated. An erased block or a partial block is then designated as the new active block, depending upon the amount of additional data to be stored, as discussed above. But if the full block contains obsolete data and the maximum offset for the file is less than the range of offset addresses that can be accommodated by a single block, then it is a full program block, according to the definition given above. It is then preferred that the block be compacted by copying its valid data to an erased block, and the original block erased. The resulting block then contains this valid data and erased capacity, which is a partial block. This new partial block then becomes the active program block. The state of the file has then transitioned from state 2 to state 1 and then back to state 2 (see
As a partial block, the active program block that exists when the file is in state 2 may be selected as a destination block for a known amount of data of another file from a source block during a reclaim operation. The identity of the program block is maintained on a list of partial blocks that includes the available erased capacity in each of the blocks on the list. The amount of data to be copied from a source block is fit into the erased capacity of a partial block on the list. If the program block for the current file is selected as a destination block for data of another file during a reclaim operation, the program block becomes an active common block of the current file, after the data of the other file is copied into its erased capacity. The file has then transitioned from state 2 to state 3 (see
Additionally, while the file is in state 2, there is a possibility that the data written into the program block for the file may be copied into another block that is a partial block storing data of another file, as part of an operation to reclaim the program block. In this situation, the destination block of the reclaim operation becomes an active common block. The file has transitioned from state 2 to state 4. Further data for the file are now written into the common block, which is the active block for the file.
When the active common block of a file in state 2 becomes full, it is designated as a full common block. The file is then contained in the limit of two fractal blocks, the full common block and the program block. Since another fractal block may not be allocated to receive data of the file, data of the file may be copied from the program block into an erased block and this new block is then designated as an active program block for the file. Such copying of file data as part of the file state transition is identified herein as a “data transition”, and is so noted in
Any data transition is completed as a single operation before the state transition can be considered to be complete. This means that if the file needs an active block into which data may be written, other operations cannot be performed by the memory until the data copying part of the data transition is complete. This data copying is therefore typically not interleaved with other memory operations over time.
A transition from file state 4 to state 3 occurs when its program block is designated to be a reclaim block. Data of the file in the program block are moved to a common block as part of a reclaim operation, after which the common block becomes the active block for the file. Further, once the active common block of a file in state 4 becomes full, the file is stored in two fractal blocks. Another block cannot be allocated as the active block until one of the fractal blocks is eliminated. Data in the program block are therefore moved (data transition) to erased capacity of a partial block as part of a transition from state 4 to state 7, thereby eliminating the fractal program block. The resulting common block then becomes the active block for the file.
When in state 3, data of the file are being written into an active common block. If data of the file are moved during a reclaim operation from the active common block to erased capacity of a partial block, the destination partial block becomes an active common block to which further data of the file are written. The file has then transitioned from state 3 to state 6. But if a good fit of the amount of data to be moved from the source program block cannot be made with the capacity of a partial block on the partial block list, the file data in the common block are moved from that block to an erased block and that erased block becomes an active program block for the file. The file has then transitioned from state 3 to state 2. In the course of this state transition, allocation of an active block includes making a data transition from the original common block to the new erased block, which then becomes the an active program block for the file.
A further possibility when the file is in state 3 is that the active common block to which data of the file are being written becomes full. The file then has no active block to which further data may be written, and has transitioned to state 5. This state is similar in operation to that of file state 0, in that there is no active block for the file but it is different in that data of the file is contained in a full common block when the file is in state 5. When in state 0, there is no fractal block containing data of the file. Both states 0 and 5 are usually temporary states from which a transition takes place as soon as additional data of the file are to be written.
When in state 5, the possible transitions to other file states are similar to those when the file is in state 0 except that some data of the file are stored in a common block when in state 5 and not when in state 0. An erased block is allocated for additional data of the file if the amount of data is unknown, thus creating an active program block and transitioning the file to state 8. If the amount of data are known, they are written into remaining capacity of a partial block, if a good fit of sizes can be made, thereby causing the partial block to become an active common block, and the file transitions from state 5 to state 7. File state 8 is similar to state 2, except that data of the file are stored in a full common block when in state 8 and no such block exists when in file state 2. File state 7 is similarly related to file state 3.
When in file state 6 and the active common block is filled with data, the file is then stored in a full common block and common block. Since the limit in this embodiment of two fractal blocks has been reached, another block cannot be allocated as a program block or some other fractal block. Therefore, a data transition needs to take place. Data of the file from one of the common blocks are moved either into a partial block (file transition to state 7), which then becomes an active common block for the file, or into an erased block (file transition to state 8) if a suitable fit of the data with the erased capacity of a partial block cannot be made.
When in file state 7, the active common block can become full. The file is then being stored in two full common blocks, transitioning to state 9.
Also while the file is in state 7, the common block may be designated as a reclaim block, so data of the file then needs to be relocated. A data transition then takes place. If data of the file are moved from the common block to an erased block, which thereafter becomes an active program block, a transition to file state 8 has taken place. If data of the file are instead moved into a partial block, the partial block then becomes a common block and the file state remains 7.
File state 9 is a stable state, since a file may remain with two full common blocks for a time during which no additional data are written to the file. But there is no active block designated when the file is in that state. Since the limit of two fractal blocks exists, a data transition must therefore be made before additional data can be written to the file. In the one case, all the data of the file in one of the two full common blocks may be moved to an erased block and this block then becomes an active program block for writing new data of the file. The file has then transitioned from state 9 to state 8. But if the amount of data of the file in one of the two full common blocks plus additional data of the file total less than the capacity of a block, then enough erased space is sought in a partial block. If found, data of the file from one of the full common blocks are moved into the partial block and it then becomes an active common block for writing the additional data for the file. This results in a transition from state 9 to state 7.
When in file state 8, data of the file are being written to an active program block while other data of the file remain stored in a full common block. When the program block becomes full, it becomes a file block and there is no longer an active block for the file. The state then transitions to state 5, where a further file transition allocates either an erased block or a partial block as the new active block, as described above.
But when in state 8 and the active program block of the file is selected as a destination block for a reclaim operation, the file state transitions directly to state 7, in a first case. This creates a common block which is active to receive the new data of the file. Alternatively, if the active program block for the file when in state 8 is designated as the source block of a reclaim operation, data of the file are moved into a partial block which then becomes an active common block for writing additional data to the file. The file state has also transitioned from state 8 to state 7, in a second case.
In addition to the primary file state transitions illustrated in
The rendering of data to be obsolete in these circumstances causes the types of blocks in which the obsolete data are stored to change, with a resulting change in the state of a file. When a new active block is needed for data of the file, it is selected in the manner described with respect to
The transitions of
Information of the file state is used for determining the type of block to be allocated as the active block for the file when data are to be programmed for a file and no active block currently exists for the file. The table of
The operations described above may be carried out by the processor 27 of the controller 11, executing stored firmware, in the example memory system shown in
As described above, part of the block management includes reclaiming unused capacity in blocks for the storage of new data. This is not of particular concern when the amount of data stored in the memory system is far less than its capacity but a memory system is preferably designed to operate as if it is full of data. That means that blocks which contain only obsolete data, and other blocks that contain valid data but also have some obsolete data and/or unwritten erased pages, can be dealt with in a manner to reclaim this unused capacity. The goal is to utilize the storage capacity of the memory system as completely as possible, while at the same time minimizing adverse effects on performance of the system. Reclaiming of blocks is noted as 617 in the overall system operation diagram of
Any valid data in a block designated for a reclaim operation (source block) is copied into one or more blocks (destination blocks) with sufficient erased capacity to store the valid data. The destination block is selected in accordance with the block management techniques described above. The data of each file stored in the source block are copied to a type of block that is selected on the basis of the state of file and other factors, as described above. Examples of data copying between different types of files as part of reclaims operation are given in
The block 683 of
The block 691 of
As a result of each of the four specific examples of reclaim operations shown in
The deletion of a file from the memory also commonly causes data of the file in one or more fractal blocks, such as a common block or a full common block, to become obsolete. That block is then subject to a reclaim operation since the remaining valid data of another file will be less than the storage capacity of the block and can be a small amount.
A reclaim operation is shown in general terms by a flowchart of
The list(s) of such blocks changes constantly as data are written, updated, moved, deleted, and so forth. Changes that result in blocks changing their types to and from partial, obsolete and invalid cause the list(s) maintained by the step 701 of
In a step 703, a single reclaim block is preferably identified from those on the updated list(s) as the next in order to be reclaimed. If a partial or obsolete block, it is a source of valid data to be copied into another block referred to as a destination block. Several specific techniques that may be used to select the source block are described below.
A next step 705 then determines whether it is appropriate to perform the reclaim operation at the current time, considering the memory operations that need to be performed in response to commands of a host. If the host has sent an idle command to the memory system, or something similar that indicates there will be some period of time when the host will not be expecting the memory system to perform a particular operation, then the memory system is free to carry out overhead operations in the foreground including a reclaim operation. Even if the memory system is busy writing data to or reading data from the memory in response to a host command, the reclaim operation, particularly its data copying, can be interleaved with data write and read operations. Such interleaving is described in U.S. patent application Ser. No. 11/259,423 of Alan Sinclair, filed Oct. 25, 2005, publication no. 2007/0033324 A1, and Ser. No. 11/312,985 of Alan Bennett et al., filed Dec. 19, 2005, publication no. 2006/0161728 A1.
If it is determined by the step 705 that a reclaim operation may be carried out, the process differs depending on whether the identified reclaim block contains valid data, and, if so, whether it contains valid data of more than one file. If a partial block or obsolete block, it will, by definition, contain valid data, and, if a common block or a full common block, will contain valid data of two or more files. Whether or not there is valid data in the reclaim block is determined by a step 707. If there is valid data that must be moved, data of a single file are identified and a destination block is identified to receive that data, in a next step 709. The destination block is identified by the process described above with respect to
Returning to the step 707, if the source block contains no valid data, which is the case for an invalid block, there is no valid data to be moved. The source block only needs to be erased. The processing therefore, in that case, bypasses the steps 709 and 711, as shown in
In a first embodiment of the process of
This first embodiment of the process of
Therefore, in other embodiments of the process of
In these other embodiments of the process of
In a second embodiment of the reclaim block identification step 703 of
If there are no blocks on either of the invalid or obsolete lists, then a block on the partial block list is chosen in step 703 as the reclaim block. Although a partial block could be chosen to be that with the least amount of valid data, it is preferred to rank the partial blocks in a way that recognizes the benefit of their erased capacity. For this purpose, a “reclaim gain” can be calculated for each partial block, as follows:
where S is the block size in terms of its total number of data storing pages, E is the number of pages of erased capacity into which data may be written and V is the number of pages containing valid data that needs to be moved to another block. A constant k is included to weight the positive effect of the erased capacity of the block but can be set at 1. As the value of kE increases, the resulting reclaim gain goes down. As the value of V goes up, the reclaim gain also goes down. The partial block with the highest value of reclaim gain is selected in the step 703 as the reclaim block. Other mathematical expressions can alternately be used to define a reclaim gain in terms of E and V that balance the detriment to system operation of containing valid data and the benefit of having erased capacity. The reclaim gain may be calculated each time there is a change in the block, such as each time data are written into its erased capacity, and stored as part of the information maintained by file directory or FIT.
This second embodiment is illustrated in
A third embodiment is shown by a flowchart of
A step 747 identifies the block on the obsolete block list that contains the least amount of valid data. It is then determined whether at least one block exists on the partial block list, by a step 749, and, if so, the block with the least amount of valid data is identified, in a step 751. A next step 753 then makes a choice between the one block identified from the obsolete block list and the one block identified on the partial block list. For this purpose, a quantity (V+kE) is calculated for the block identified from the partial block list in the step 751, the terms V, E and k being the same as used above. It is this quantity that is compared with the amount V of valid data in the block identified in step 747 from the obsolete block list. If the (V+kE) quantity for the partial block is greater than V of the obsolete block, then the obsolete block is chosen as the reclaim block, in a step 755. But if the V of the obsolete block is greater than the (V+kE) quantity of the identified partial block, then the partial block is selected in a step 757 as the reclaim block.
By adding the erased capacity quantity kE of the identified partial block to its valid data V before comparing with only the valid data V of the identified obsolete block, the process is biased in favor of selecting the obsolete block. An identified partial block with the same amount of valid data as an identified obsolete block will be retained since it is still has a potential use to store data in its erased capacity. Indeed, a partial block having an amount of valid data that is less than that of an obsolete block by an amount kE will be retained.
Returning to the step 745 of
The third embodiment may alternatively make use of only two lists. The first list is an obsolete block list that contains entries for blocks that contain obsolete data and no erased memory capacity. Rather than using a separate invalid block list as show in
The second list in this alternative to the third embodiment is a partial block list that contains entries for blocks that contain some erased memory capacity. The blocks may optionally contain valid data. Each entry in the list has a field containing a value defining the amount of valid data in the block to which it relates. The entries in the list are ordered according to the values in these fields. A block may be selected from the head (block with the least amount of invalid data) of either the first or second list by the technique of step 753 of
A table of
The processes described above with respect to
Although the various aspects of the present invention have been described with respect to exemplary embodiments thereof, it will be understood that the present invention is entitled to protection within the full scope of the appended claims.
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|U.S. Classification||711/103, 711/E12.008|
|Cooperative Classification||G06F3/0644, G11C16/102, G06F3/0613, G06F3/0643, G06F3/0605, G06F3/0679, G06F17/30218, G06F3/0608, G11C16/0483, G06F2212/7202, G06F3/064, G06F12/0246, G06F2212/7205, G06F3/0652|
|European Classification||G06F12/02D2E2, G06F17/30F8F, G06F3/06A2C, G06F3/06A2P4, G06F3/06A4F4, G06F3/06A4H6, G06F3/06A4F6, G06F3/06A4F2, G06F3/06A2A2, G06F3/06A6L2F|
|Jun 12, 2006||AS||Assignment|
Owner name: SANDISK CORPORATION, CALIFORNIA
Free format text: ASSIGNMENT OF ASSIGNORS INTEREST;ASSIGNORS:SINCLAIR, ALAN W.;WRIGHT, BARRY;REEL/FRAME:017764/0197
Effective date: 20060504
|Jun 2, 2011||AS||Assignment|
Owner name: SANDISK TECHNOLOGIES INC., TEXAS
Free format text: ASSIGNMENT OF ASSIGNORS INTEREST;ASSIGNOR:SANDISK CORPORATION;REEL/FRAME:026380/0401
Effective date: 20110404
|Apr 22, 2015||FPAY||Fee payment|
Year of fee payment: 4